Upload
others
View
0
Download
0
Embed Size (px)
Citation preview
International Research Journal of Environment Sciences________________________________ ISSN 2319–1414
Vol. 4(4), 96-103, April (2015) Int. Res. J. Environment Sci.
International Science Congress Association 96
Review Paper
Application of geotextiles in Coastal Protection and Coastal Engineering
Works: An overview
Mitra Ashis Visva-Bharati University, Department of Silpa-Sadana, Textile Section, Sriniketan, Birbhum, WB-731236, INDIA
Available online at: www.isca.in, www.isca.me Received 13th January 2014, revised 17th February 2015, accepted 5th March 2015
Abstract
Geotextiles, one of the branches of technical textiles, are permeable textile materials or fabrics used for various civil
engineering and other geotechnical applications. Geotextiles were one of the first textile products used in human history,
and invention of geotextiles forms a bridge between civil engineering and textile technology. The application areas of
geotextiles are very wide and during the last decade the areas have expanded further very fast worldwide. With the rapidly
growing technological advancement, geotextiles have made inroads into a large variety of domains and have been
acclaimed all over the world because of some of their built-in advantages like easiness and flexibility of use, softness (as
compared to monolithic and rock constructions), rapidity of installation and long term efficacy. Geotextiles provide
a relatively safe and economically feasible solution to day-to-day engineering demands and construction challenges.
Used as replacement of natural materials, geotextile products perform a wide range of functions such as erosion control,
soil stabilization, filtration, drainage, separation and reinforcement requirements. Geotextile bags, tubes and containers
made with geotextiles are playing a proactive role in hydraulic, coastal, offshore engineering and river protection works
as eco-friendly, construction-friendly and cheaper alternatives of conventional protection and engineering methods which
are generally hard, expensive, temporary (having short life), and not environmental-friendly. The global geotextile market
is enjoying strong growth but it is also highly competitive. In this paper, the constructional and functional aspects of
geotextiles have been highlighted, and the potential role of various geotextile products in the domain of coastal protection,
coastal engineering and off-shore engineering has been elaborated with some real-life ventures both in India and abroad.
Keywords: Geotextiles, Geosystems, Groins/Groynes, Dykes, Revetment, Levees, Breakwaters.
Introduction
Geotextiles, one of the branches of technical textiles, are permeable textile materials or fabrics used for various civil engineering and other geotechnical applications. Invention of geotextiles, probably the first textile products in human history, forms a linkage between civil engineering and textile technology. Excavations of ancient Egyptian sites show the use of mats made of grass and linen. Geotextiles have been used for thousands of years. In the days of the Pharaohs, geotextiles were primarily used in roadway construction to stabilize the body and the edges of roadways. These primitive geotextiles were made of natural fibres, fabrics or vegetation mixed with soil to enhance road quality, particularly when roads were made on unstable soil
1-2.
The term ‘geotextile’ was first coined by Giroud and Perfetti in 1977. Before 1988, geotextiles were called plastic filler cloth or filter fabric
1. Geotextiles were first introduced into civil
construction projects in the USA and Europe in the 1960s for road construction due to their efficient drainage and separation functions. From that point onwards, the technology developed so rapidly that it was an urge to organize the first International Conference on Geotextiles in Paris in 1977. The International Geosynthetics Society (IGS) was founded in 1982 because of
the need for greater knowledge and understanding of the material
3.
Geotextiles are either woven or non-woven permeable fabric or synthetic material which can be used in combination with geotechnical engineering material. They are applied in a broad range of civil engineering applications including construction, paving, drainage and other applications. Geotextiles are profusely employed with soil, rock, earth or any other geotechnical engineering-related material.
The application of geotextiles has now-a-days expanded to such an extent that virtually every civil construction project employs a member of geosynthetic family. The marine and coastal environment is an extremely harsh and adverse environment. Hence, geotextiles, as relatively thin light weight material, when used in that environment as replacement of costlier, heavier and permanent civil constructions, will be subjected to severe abrasion from armour rock and marine sediment, large dynamic flow conditions from both tidal action and wave impact. Consequently, geotextiles used in coastal and marine environment must be able to resist conditions which are far more aggressive than the road construction applications. Coastal erosion and accretion are inevitable processes as the coastal sediments are constantly in motion as an effect of tides,
International Research Journal of Environment Sciences______________________________________________ ISSN 2319–1414
Vol. 4(4), 96-103, April (2015) Int. Res. J. Environment Sci.
International Science Congress Association 97
waves, winds, and currents. Human activities such as sand dredging and harbour construction have been disrupting the continuity of sediment transport and accelerate the coastline erosion. In addition, climate change, sea level rise, and storm surges added another layer of complexity to the eroding coasts
4.
Coastal structures are built to prevent further erosion of shorelines as well as restoring the eroded beaches to their initial phase. Hence, without coastal protection measures, eroded coastline can ravage the public properties. Therefore, coastal structures are imperative to protect the environment, ecology, infrastructures, and economic activities near shore
5.
The conventional coastal structures (i.e., breakwater, groins, revetment, and seawalls) have been constructed using wood, rock, and concrete. Nonetheless, the recent consideration of environmental approaches and the limited resources of natural rocks in certain regions led to an increase in the application of geosynthetics in coastal protection
6.
Therefore, for the design of new, cost effective shore protection structures as well as for the reinforcement of existing threatened coastal barriers and structures, including dune reinforcement and scour protection
7, more versatile materials and innovative
solutions are required, which will supplant the conventional methods most of which are hard, short lived, expensive and not eco-friendly. The recent trend in the mitigation of coastal erosion and costal protection has been shifted now-a-days towards soft yet novel and eco-friendly methods. Pro-active methods and solutions are being developed and employed, which are not only eco-friendly, construction-friendly and cheaper but also address the root cause of the problem without much ‘adverse effects’. Many contemporary ways are being used more and more to armour, stabilize, or restore beeches, including the use of patented precast concrete units, geotextile sand-filled bags, green belts, bio-engineering, sand fencing, beech-face dewatering systems, and integrated coastal protection methods. Retreat from the coast is also thought about, in many circumstances
8.
Geotextiles and geosynthetics
Construction and raw materials used: Geotech segment
comprises of technical textile products used in geotechnical
applications pertaining to soil, rock, earth etc. This class of
products is loosely called Geotextiles. However, geotextiles
particularly refer to flat, permeable, polymer-synthetic or
natural textile materials which can be non-woven, woven,
knitted or knotted materials. They are used in contact with soil
or rock and/or any other geotechnical materials in civil
engineering earthworks and building constructions. In fact,
geotextiles is one of the members of the geosynthetic family
which comprises of geogrids, geonets, geotextiles,
geomembranes, geosynthetic clay linters, geopipe, and
geocomposites1-3,9
.
Geotextiles are made from polypropylene (PP), polyester (PET),
polyethylene (PE), polyamide (nylon), polyvinylidene chloride
(PVC), and fiberglass, and their GSM varies from under 40 to
over 3000 which is mainly used in landfill end uses. PP and
PET are the most widely used. Sewing thread for geotextiles is
made from Kevlar or any of the above polymers9-10
. Different
fabric composition and construction are suitable for different
applications.
To survive aggressive underground environments, geotextiles
must be resistant to various forms of attack, such as mechanical,
chemical and biological. Chemical attack may be initiated
directly by acidic and alkaline soils or indirectly by the active
wastes present in the landfills. Depending on the type of
chemical compound, changes in the polymer structure can be
brought about by oxidation, chain scission, cross linking,
swelling or dissolution of the polymers, volatilization or
extraction of ingredients of the polymeric compound, or an
increase in the crystallinity of the polymer. In addition the
service temperature may accelerate the effects of chemical
degradation.
Types, desired characteristics and functions: In general, the
vast majority of geotextiles are made from polypropylene or
polyester and formed into the following fabric categories2,9
:
Woven monofilament, Woven multifilament, Woven slit-film
monofilament, Woven slit-film multifilament, Nonwoven
continuous filament heat bonded, Nonwoven continuous
filament needle-punched, nonwoven staple needle-punched,
Nonwoven resin bonded, other woven and nonwoven
combinations, Knitted.
The non-woven geotextiles provide planar water flow in
addition to stabilization of soil. Typical applications include i)
access road and rail building, ii) dam, canal and pond lining, iii)
hydraulic works, sewer lines, iv) asphalt pavement overlays, v)
soil stabilization and reinforcement, vi) soil separation, vii)
drainage, viii) landfill, ix) filtration, x) weed control, xi) sport
surfaces, xii) drainage channel liners, xiii) sedimentation and
erosion control, etc. Woven geotextile looks like burlap. It is a
fabric made of two sets of parallel strands systematically
interlaced to form a thin, flat fabric. The strands are of two
kinds - slit film which are flat, or monofilaments which are
round. Woven geotextiles are generally preferred for
applications where high strength properties are needed, but
where filtration requirements are less critical and planar flow is
not a consideration9-10
. Woven geotextiles are mainly used in
coastal works, embankment and in or near dams, waterways,
and woven geogrids for reinforcement. Both woven and knitted
geotextiles are beneficially used for a wide range of both
cohesive and non-cohesive soils and they support quick
formation of a natural soil filter. They facilitate dissipation of
pore pressures and, thanks to their strength characteristics and
low elongation, they improve mechanical properties of soil and
enable the construction of reinforcing ground structures in this
way10
.
The desired characteristics of woven geotextiles are: i) Ability
International Research Journal of Environment Sciences______________________________________________ ISSN 2319–1414
Vol. 4(4), 96-103, April (2015) Int. Res. J. Environment Sci.
International Science Congress Association 98
to resist clogging, ii) Excellent elongation at break, iii)
Excellent water permittivity, iv) Good grab tensile strength, v)
Good puncture resistance, vi) Trapezoidal tear strength, vii) UV
resistance, viii) Very good Mullen burst, etc.1.
There are mainly four segments of Geotech family namely, i)
Geogrid, ii) Geonet, iii) Geomembrane, and iv) Geocomposites.
Geotextiles perform one or more basic functions in a structure
like filtration, drainage, separation, erosion control, sediment
control, reinforcement, and (when impregnated with asphalt)
moisture barrier. In any one application, a geotextiles may be
performing several of these functions.
Solutions incorporating geosystems: Geosystems are systems
of geotextile encapsulated granular soils that may be used to
replace rock as conventional building blocks in coastal and
marine engineering structures. They include geotube systems,
geocontainer systems and geobag systems. Geotube systems
involve tubular units that are typically hydraulically filled.
Geocontainer systems involve units that are tailor made to
match split bottom barges; within which the units are filled,
sealed and dropped into position. Geobag systems involve a
wide array of bag designs and geometry, and are typically dry
filled in site, sealed and deployed11-12
.
Role of geotextiles in coastal protection and off-
shore engineering
Due to sea or river current, fine soils of the bank start migrating
causing erosion. Conventional design of cementing the banks is
not a solution due to hydraulic pressure of the soil. Only feasible
solution is the application of geotextiles or geosynthetics.
Geotextiles allow water to pass through but resist the fine soil
migration.
Coastal protection measures are designed to protect inland
flooding and minimise the erosion of the coastline caused by the
constant motion of the sea. Geotextiles protect the coast line as
their flexibility and permeability ensure withstanding of the
impact of waves and currents, preventing erosion and washing
out of lines (figure-1).
Figure-1
Geotextiles preventing coast line erosion
Geosynthetics are used in various coastal protection applications
such as filters in dykes and dams, for foundations under groynes
and breakwaters, as well as by using geotextile containers as
structural elements in groynes, seawalls, breakers or for bed and
embankment stabilisation.
Woven geotextile containment systems in tubular forms filled
with locally available sand/slurry are formed in-situ on land or
in water to protect shore and marine environments. Geotextile
tube, for example, is one of the geosynthetics structures that are
increasingly used in coastal protection. Geotextile tubes are
made from high-strength geosynthetic fabrics that allow the
water to flow through pores while retaining the filing materials.
They are widely used for dewatering, flood control, and coastal
protection. Geotextile tube can be used in various conditions as
a result of the low consumption of construction cost and time,
requirement of simple equipment, and low skilled workers.
Geotextile tubes are good alternatives for the conventional hard
coastal structures6.
Geotextile tubes are used as a cost-effective alternative to
mitigate erosion on coastal shorelines, riverbanks, and lakes
using readily available materials for infill. Geotextile tubes
filled with dredged materials or sand and strategically placed
will dissipate the wave energy, as well as provide structural
support against other erosive forces. Geotextile tubes can be set
in place along shorelines and river fronts either to be left
exposed to battle the elements, or incorporated into the
environment as part of a manmade dune or riverbank. They can
also be placed in the water to serve as jetties and groins10
.
Geotextile Sand Containers (GSC), for example, is another low
cost, soft and reversible solution for the above problem and it
has a history of more than 50 years in hydraulic and marine
applications. Coastal structures built with GSCs are obtained by
substituting rocks or concrete units with containers made of
geotextile and filled with locally available sand or slurry. A
range of successful coastal protection structures using GSCs
have been constructed in many parts of the world, especially in
Australia and Germany7.
Working principle of geotextiles/geosynthetics
Due to the continuous action of waves, tides, currents and other
water motion, coastal and marine environments are susceptible
to erosion, the consequence of which can range from a simple
loss of surface soil to the wholesale undermining and collapse of
structures. To positively influence the morphology and prevent
erosion at designed locations a variety of measures are used.
Generally, these measures fall into one of three categories:
Geometrical measures, where the shape of the structure and
adjacent profile is altered in order to reduce the water forces
below a minimum threshold. Stabilisation measures, where the
exposed structure is protected from erosion by stabilising the
susceptible soil. Examples include the provision of revetments,
etc.
International Research Journal of Environment Sciences______________________________________________ ISSN 2319–1414
Vol. 4(4), 96-103, April (2015) Int. Res. J. Environment Sci.
International Science Congress Association 99
External measures, where the exposed structure is protected
from erosion by the provision of a protection structure, placed at
some distance. Examples include breakwaters, etc.
TenCate® and Terrafix® Geosynthetics, for example, with
filtration, containment or reinforcement functions, are used as
integral components in the design and construction of a variety
of coastal and marine structures such as revetments, scour
protection layers, levees, dykes, groynes/groins, jetties and
breakwaters. These Geosynthetics are easy to install beneath the
water surface, in difficult conditions, and once in place provide
continued performance11-12
.
The conduction of the coastal protection measures is
significantly site dependent as there are various interrelated and
locally diverse parameters. These parameters include sediment
properties, water elevation, wave and current characteristics,
geomorphology setting, protection goals, required intervention
level, safety level, and social, economic, and politic factors.
Coastal protection methods for the sandy beaches, for example,
focus on erosion prevention and beach restoration, while, for the
mudflat, protection and rehabilitation of mangrove can be
considered as a key method. Construction cost is one of the
major considerations for the selection of coastal management
method6.
Coastal and marine structures as measures of
coastal protection and coastal engineering11-19
Stabilisation of dykes: Dykes and related structures typically
consist of a general rock fill core and an outer armour protection
for long term design against wave and current attacks. Needle-
punched geotextiles are used to protect the coastline when used
in the toe area of sea walls and dykes. They improve the
construction efficiency if the sea currents cause surface erosion
or unacceptable soil displacement. The three-dimensional,
labyrinth-like pores and channels of needle-punched nonwovens
are not only similar to the soil structure itself, but, if correctly
designed, also increase the stability of the revetment against
impact stress caused by the motion of the sea.
A geotextile with a minimum mass per unit area of 600 g/m² is
necessary wherever type II or III armor rock with individual
weights ≤ 60 kg are placed directly on geotextiles, or where
concrete revetments for high-stress applications have been
installed. Where individual stone weights exceed 60 kg,
geotextiles with yet a higher mass per unit area is
recommended. In the case of low-stressed dykes, filter
geotextiles (like Terrafix®) with a minimum mass of 500 g/m²
and minimum thickness of 4.5 mm serve to encapsulate and
stabilise the sand core from erosion. When flooding occurs, they
prevent washout of the sand and ensure the stability of the dyke.
Top soil as well as concrete blocks can act as an effective cover
layer over the geotextile12
.
Coastal revetments: A revetment is a facial or veneer layer
applied to the sloping surface of soils to prevent their erosion
against wave action and currents. Revetments are often used to
protect coastlines. Coastal revetments may be deployed to
protect toes of coastal cliffs, bluffs, dunes, etc, and to fortify
coastal embankments and flood levees. Functionally, as
slopping structures, revetments reduce wave reflection and
absorb wave energy through a combination of energy
dissipation within the structure and wave run-up over the
structure surface. They may also serve other purposes such as
limiting wave overtopping or wave reflections. Natural sand
dunes may be found at the landward extent of an active beach
and can offer some form of protection against wave attack under
extreme tidal or surge conditions. When natural dunes do not
exist or when they do not provide sufficient protection, rock
revetment structures may be built hidden within covered sand
for beach aesthetics and recreation purposes. During an event of
storm, erosion of the front sand cover may take place but the
exposed revetment would prevent further damage from
occurring. After the storm event, the sand cover is then
replaced11-13
.
TenCate® and Terrafix® Geotube Systems, for example, are
commonly used as a very cost effective alternative to hidden
revetments in the sand dune zone.
Levees and flood control dykes: Sea levels rise above inland
areas due to many reasons. One of the reasons is tides. Tides
result in regular rise and fall in sea levels. Although the typical
tidal range in the open ocean is about 0.6 m, coastal tidal ranges
can vary between zero to over 10 m in height, depending on the
coastal geography and location. Due to global warming, the
mean sea level is expected to gradually rise with time. Water
levels can also rise as a result of waves and surges.
Flood control dykes or levees are constructed along estuaries
and coastlines to protect flooding of low lying areas. The top of
flood control dykes or levees should be higher than the design
high water level plus a safety freeboard. In addition the levees
should be designed to prevent seepage through the core
structure11-13
.
Estuarial barriers and barrages: Tides cause sea levels to rise
and fall in constant cycles. Tidal effects are experienced in
coastal and river delta areas. Estuarial barriers and barrages
allow river discharges while holding back rising sea levels.
They are special dam structures that are designed to hold back
the sea during high sea levels while allowing river discharges
during normal sea levels. The primary objective of such
structures is usually flood prevention11-12
.
Coastal groynes/groins: Groynes are finger-like hydraulic structures that jut perpendicularly out of coastlines. Their primary engineering function is to interrupt or reduce long-shore sediment transport. This interruption will produce accretion updrift of the groynes and produce concomitant erosion downdrift of the groynes. Groynes are usually constructed in
International Research Journal of Environment Sciences______________________________________________ ISSN 2319–1414
Vol. 4(4), 96-103, April (2015) Int. Res. J. Environment Sci.
International Science Congress Association 100
groups otherwise referred to as groynefields. When constructed in concert with beach restoration, the groyne field will act to reduce future beach maintenance and nourishment requirements. The sectional requirement of a groyne structure is the same as that of a basic dyke structure. Geotextiles are used as a filter layer to prevent sand beneath from being eroded away. Alternatively, Geotube Systems may be used to construct coastal groynes
11-12, 14, 16-17.
Land reclamations: The shortage of land along certain coastlines requires land to be reclaimed from the sea. Reclamation dykes are cofferdam units that retain fill while providing protection against wave attack during construction, prior to placement of long term armour protection cover. Conventionally, the cofferdam units are constructed of rock fill material in much the same way as the rock fill core of groynes, jetties, etc. Depending on the grading of the rock fill material, geotextiles may be laid on the inner side of the reclamation dyke to prevent washout of sand fill through the rock fill dyke. Geotextiles may also be laid over the sea side of the reclamation dyke prior to placement of the armour protection. Alternatively, Geotube Systems and Geocontainer Systems may be used to replace the rock fill reclamation dyke
11-12, 14-19.
Creating islands: Artificial islands are constructed for a variety of reasons. They may provide land for development of prime residential and commercial properties; create eco-friendly habitats and sanctuaries; act as barrier islands to protect coastal habitats,etc. Reclamation dykes are used to form the shorelines of the islands in very much the same way as land reclamation techniques. Geotextiles may be laid on the inner side of the reclamation dyke to prevent washout of sand fill through the rock fill dyke. Geotextiles may also be laid over the sea side of the reclamation dyke prior to placement of the armour protection. Alternatively, Geotube Systems and Geocontainer Systems may be used to replace the rock fill reclamation dyke
11-
12, 14-17.
Coastal breakwaters: Coastal breakwaters are marine structures that have the primary function of sheltering a coastal development by preventing longshore currents from causing erosion and reducing wave energies impacting a shoreline. They are connected to the shoreline like groynes and jetties but differ in function and massiveness. Like groynes and jetties they impact the littoral functions but coastal breakwaters differ with the additional function of forcing waves to break offshore. Coastal breakwaters also tend to have special end details in the sea e.g. fishtailed, L-shapes or T-shaped that are designed to eliminate problems of downdrift erosion and promote the formation of beaches. Geotextiles are used as filter layers for the construction of coastal breakwaters. Geotextiles can also be prefabricated onshore into a large panel of fascine mattress that can be floated out to sea. This panel of fascine mattress can then be ballasted into position on the seabed by dropping rock onto the floating fascine mattress. Alternatively, Geotube Systems, Geocontainer Systems and Geobag Systems may be used to replace the rock fill core of breakwaters
11-12, 14, 16.
Offshore breakwaters: Offshore breakwaters are marine structures that have the primary function of reducing wave energies impacting a shoreline. Offshore breakwaters reduce wave energies by partially reflecting some wave energy seawards as well as forcing some wave energies to be expensed through wave breaking on the structure before such destructive waves can reach the shoreline. Offshsore breakwaters are generally constructed parallel to shorelines. Offshore breakwaters are sometimes designed to be permanently submerged and are often designed to retain a perched or artificial beach. As offshore breakwaters tend to involve construction in relatively deep waters, the installation of geotextiles can often be challenging. Geotextiles can be specially designed to make installation in deep waters a simple and efficient task. Construction of this marine structure is just similar to that of coastal breakwaters
11-12, 14, 16-19.
Some major applications as measures of coastal
protection or coastal engineering
Applications in India: In India, the use of geotextile tubes for
the purpose of coastal defense started in the last decade. In
Indian scenario, the use of sand-filled geotextile tubes for the
coastal protection works is in the developing phase. The
compilation and analysis of the data regarding success/failure of
projects may improve the techniques of using geotextile tubes20
.
The below is mentioned a few real-life projects on application
of geotextile products for coastal protection and off-shore
engineering works: Installation of geotextile bags and geotextile
tubes along the coast line of the Bay of Bengal from Shankarpur
to Haldia, West Bengal (figure-2). Nearshore geotextile tubes
reef at the coastal area of INS Hamla, Malad (W), Mumbai. The
coast at the INS Hamla has been facing sea erosion since last
few years. In order to mitigate the erosion, the project
authorities constructed a 900 m vertical UCR wall at the eroding
coast along with the beach nourishment. The geotextile tubes
laying and beach nourishment work were completed in the
month of March, 2010. Application of geotextile tubes to
protect sea wall of Uppada, Andhra Pradesh. Reclamation
bundh using imported geotextile containers at Adani Port,
Gujarat (figure-3). Installation of geotextile tubes at Devbag,
Malvan, Maharashtra to mitigate severe erosion during 2006
monsoon. Tubes were aligned parallel to the coast, having a
total length of 150m. Application of nearshore geotextile tubes
reef at Candolim beach situated at about 15 km north of the
Panjim, Goa, the construction of the off-shore reef with
geotextile tubes for a length of 800 m and the beach
nourishment work were completed in the April 2010. Nearshore
geotextile tubes reef at Dahanu, about 110 km north of Mumbai,
Maharashtra, The beach is extensively used by the tourists for
recreational activities. About 400 m length of the beach is
protected by constructing PCC retaining wall with steps towards
sea side to facilitate the tourists. The beach is also enhanced by
providing beach nourishment. A series of off-shore reefs with
sand-filled geotextile tubes was constructed to hold the
nourished sand in the year 2010-2011.
International Research Journal of Environment Sciences______________________________________________ ISSN 2319–1414
Vol. 4(4), 96-103, April (2015) Int. Res. J. Environment Sci.
International Science Congress Association 101
Figure-2
Installation of geotextile tubes
Figure-3
Reclamation bundh using geotextile container
Applications in abroad11-12
: Coastal Revetment, CT, USA, The
town of East Lyme in CT, USA wanted to connect two separate
beaches facing the Atlantic Ocean with a new elevated
pedestrian and bike path. This elevated pedestrian and bike path
would also serve as a buffer to an existing high speed train line
that was located beside it. A coastal revetment was constructed
to protect the new coastline. The armour layer of the coastal
revetment consists of approximately 1.8 m of large heavy rip
rap. TenCate geotextiles were used as filter layer underneath the
rip rap (figure-4).
Figure-4
Coastal revetment, CT, USA
Flood Control Dykes, Germany: The Big Flood of 1953 that
affected the Netherlands also caused flooding and severe
damages to land and property in northern Germany. As a result,
a 7 km long flood control coastal dyke was constructed
beginning in 1992. The 8.8 m high dykes facing the North Sea
at Leybucht would keep inland areas of up to 31 km from
flooding during extreme events. TenCate geotextiles were used
as filtration layer beneath the rock armour protection for the
dyke as well as for the bed protection in the inlet-outlet channel.
Geotube systems were used as reclamation dyke to raise the
earthworks platform above high water levels (figure-5).
Figure-5
Flood control dyke, Germany
Eastern Scheldt Barrier, The Netherlands: The Eastern
Scheldt Barrier is part of the Delta Project to protect the
Netherlands against a repeat of the big flood of 1953. The
Eastern Scheldt Barrier with a length of 8 km, seals of an
estuary with a tidal volume of 2.2 billion m3. TenCate
geotextiles are supplied for the fabrication of foundation
mattresses for the 65 prefabricated reinforced concrete piers,
each with the height of a 12-storey building and weighing
18,000 tonnes (figure-6).
Figure-6
Eastern Scheldt Barrier, The Netherlands
Bald Head Island, NC, USA: The South Beach of Bald Head
Island in North Carolina experienced severe coastline erosion.
Geotube systems were used to construct a field 14 coastal
groynes for long term protection of 3.7 km of South Beach
shoreline. The Geotube groynes had a circumference of 2.75 m
and were underlain with a 7.3 m wide scour protection apron
(figure-7).
International Research Journal of Environment Sciences______________________________________________ ISSN 2319–1414
Vol. 4(4), 96-103, April (2015) Int. Res. J. Environment Sci.
International Science Congress Association 102
Figure-7
Geotube groyne
Bengkulu Breakwater, Indonesia: The Port of Bengkulu in Indonesia completed in 1985 is protected with two rubble mound breakwaters with approximate crest lengths of 390 m and 420 m. The heads of the breakwaters were constructed with blocks weighing up to 10 tons. A total of 110,000 m
2 of
TenCate geotextiles were used for the project (figure-8).
Figure-8
Bengkulu breakwater, Indonesia
Kerteh Breakwater, Malaysia: The onshore operation base for Peninsular Malaysia’s offshore petroleum production is situated along Kerteh Bay. Coastal erosion threatened the school and housing facilities, as well as a golf course. Offshore breakwaters together with beach nourishment was the solution of choice as this option would allow the recreational beach to be fully accessible without imposing rock structures along the shoreline. TenCate geotextiles were prefabricated onshore into large panels of fascine mattresses. These large panels of fascine mattresses were then floated offshore and sunk into position by ballasting with bedding stones (figure-9).
Figure-9
Kerteh breakwater, Malaysia
Coastal protection at Lombang Beach, Indonesia (2010) (figure-
10). Revetment of Thorpeness beach, Suffolk, UK (2011)
(figure-11).
Figure-10
Coastal protection at Lombang Beach, Indonesia
Figure-11
Thorpeness Beach revetment, Suffolk, UK
Conclusion
Geotextiles or geosynthetics which belong to the so-called
technical textiles family possess high potential in various
geotechnical and civil engineering applications including road
construction, railway track-bed stabilization, soil stabilization,
erosion control, reinforcement, separation and drainage.
Application domain is vast enough, and has been expanding in a
galloping way all over the world. Apart from the regular uses,
geosystems made with geotextiles like geotextile tubes, bags,
containers etc. are playing a proactive role in hydraulic, coastal,
offshore engineering and river protection works as eco-friendly,
construction-friendly and cheaper alternatives of the traditional
protection and engineering solutions which generally are hard,
short lived, expensive and not eco-friendly. The applications of
geotextiles or geosynthetics in the form of geocontainer,
geobag, geomat, geotube etc in various coastal and marine
structures have been highlighted as measures of coastal
protection and coastal engineering works, followed by some of
the real-life ventures in our country and abroad. It must be
remembered that due to the uniqueness of majority of the
coastal and marine structures mentioned above, the installations
of geotextiles/geosystems are application specific and require
sound understanding of the nature of problem to be solved, the
International Research Journal of Environment Sciences______________________________________________ ISSN 2319–1414
Vol. 4(4), 96-103, April (2015) Int. Res. J. Environment Sci.
International Science Congress Association 103
behavior of material to be used in real world, the optimum
utilization of machineries involved without creating so much
environmental impact etc. Actual field trials are always
recommended prior to final application. The global geotextile
market is enjoying a strong growth though it is also highly
competitive. In Indian scenario, the use of sand-filled geotextile
tubes and geobags for the coastal protection works is in the
developing phase.
References
1. Basant T. and Jahan S., Engineering use of textiles in
geotextiles, Textile Review, November (2012), available
at http://www.technical textile.net (accessed on
15/09/2014), (2014)
2. Tholkappian E., Geotextile degradation under different
environ conditions, The Indian Textile Journal, (2010)
3. Hornsey W.P., Geotextiles in specialist marine
applications: An Australia perspective over 32 years,
available at http://www.geofabrics.com.au/documents
/Specialist-marine-applications-of-geosynthetics-in-
Australia.pdf (accessed on 20/12/2014), (2014)
4. Defeo O., McLachlan A., Schoeman D.S. et al., Threats
to sandy beach ecosystems: a review, Estuarine, Coastal
and Shelf Science, 81(1), 1-12 (2009)
5. Polomé P., Marzetti S., and van der Veen A., Economic
and social demands for coastal protection, Coastal
Engineering, 52(10-11), 819-840 (2005)
6. Lee S. C., Hashim R., Motamedi S., and Song K.,
Utilization of Geotextile Tube for Sandy and Muddy
Coastal Management: A Review, The Scientific World
Journal, Vol. 2014, available at
http://dx.doi.org/10.1155/2014/494020 (accessed on
20/12/2014), (2014)
7. Dassanayake D. and Oumeraci H., Hydraulic stability of
coastal structures made of Geotextile Sand Containers
(GSCS): Effect of engineering properties of GSCS,
Coastal Engineering Proceeding, 2012, available at
http://www.academia.edu/2568576/ hydraulic_stability_
of_ coastal_structures _made_of_ geotextile_sand_
containers_gscs_effect_of_engineering_properties_of_gs
cs (accessed on 20/12/2014), (2014)
8. Hedge A. V., Coastal erosion and mitigation methods:
Global state of art, Indian Journal of Geo-Marine
Sciences, 39(4), 521-530 (2010)
9. Geotextiles: The Fabric of Erosion Control, available at
http://www.multigeo.com (accessed on 15/09/2014),
(2014)
10. Civil engineering and geotextiles, available at
http://www.edana.org/content (accessed on 15/09/2014),
(2014)
11. PIANC MarCom Working Group, “The Application of
Geosysthetics in Waterfront Areas”, ISBN: 978-87223-
188-1 (2011), available at http://www.piacn.org
(accessed on 15/09/2014), (2014)
12. Tencate; Geosynthetics for Coastal and Marine
Engineering, available at http:// www.tencate.com
/amer/Images/ BRO_marine_tcm29-31781.pdf (accessed
on 15/09/2014), (2014)
13. Nielsen A.F., and Mostyn G., Consideration in applying
geotextiles to coastal revetments, In: Australian
Geomechanics Society Sydney Chapter Symposium,
October, (2011)
14. Saathoff F., Geosynthetics in geotechnical and hydraulic
engineering. Geotecnical Engineering Handbook, Vol. 2:
Procedures, First Ed., Ernst and Sohn, 507-597 (2003)
15. GEOfabrics Limited. (2005). Designing Rock and Rip-
rap Structures with Geotextiles. Leeds, West Yorkshire,
available at http://www.geofabrics.com/downloads/
downloads.htm?category=21 andback=3 (accessed on
15/09/2014), (2014)
16. Deptt. of the Army and the Air Force; Engineering use of
Geotextiles; Army TM; July (2010)
17. Koerner, Robert M., A Brief Overview of Geosynthetics
and Their Major Applications: United States Universities
Council on Geotechnical Education and Research, (2000)
available at http://www.ce.ncsu.edu/
usucger/Teaching%20Aids.html, (accessed on
20/12/2014), (2014)
18. Oumeraci, H and Recio, J., “Geotextile sand containers
for shore protection”, Chapter 21 in Handbook of Coastal
and Ocean Engineering ed. KC Young, World Scientific,
(2010)
19. Heibaum, M., Fourie A., Girard H., Kurunaratne G.P. et
al., “Hydraulic Applications of Geosynthetics”,
Procedings of the 8th
International Conference on
Geosynthetics (8ICG), Yokohama, Japan, September, 18-
22, (2006)
20. Kudale M. D., Mahalingaiah A.V., Tayade B.R., Use of
sandifilled geotextile tubes for sustainable coastal
protection: case studies in Indian scenario, Indian
Journal of Marine Sciences, 43(7), (2014)